US2626321A - Phase inverter circuits - Google Patents

Description

Jan. 20, 1953 WEN YuAN PAN 2,626,321

PHASE INVERTER CIRCUITS Filed May 29, 1948 2 SHEETS-SHEET v1.

WEN YUAN PAN PHASE NVERTER CIRCUITS `Ian. 20, 1953 2 SHEETS- SHEET 2 Filed May 29, 1948 2 INVENTOR WEN YUAN FAN Hr/V555:-

' ATTORNEY Patented Jan. 20, 1953 PHASE INVERTER CIRCUITS Wen Yuan Pan, Merchantville, N. J., assignorto Radio Corporation of America, a corporation of Delaware Application May 29, 1948, Serial No. 30,017

My invention relates to phase inverter circuits for push-pull amplifiers or balanced loads, particularly to such circuits for radio receivers thatare energized by a rectied alternating current source of power.

It is an object of my invention to eliminate hum or ripple voltage disturbance introduced by the power supplied to the anode circuits, respectively, of a transformerless push-pull driven stage, such as a combined amplifier-phase inverter.

A further object of my invention is to provide a simplied and inexpensive circuit for balancing out or neutralizing hum or ripple voltage in a transformerless amplifier-phase inverter circuit without sacricing amplification or fidelity.

A further object of my invention is so to modify an amplifier-phase inverter circuit as to reduce hum or fluctuating voltage disturbance without the addition of circuit elements. y

In accordance with my invention, certain elements of a conventional circuit coupling a rst audio and phase inverter stage and a balanced load circuit, such as a push-pull audio frequency output amplifier stage, are changed in relative values in such manner as to balance out the hum voltage normally present in the output of the first audio and phase inverter stage.

Whereas, in push-pull amplifier circuits, hum in the anode power supply circuit has balanced out in the two halves of the push-pull circuit and has been no problem, there has been a serious problem in reducing hum in the preceding stage, ordinarily a stage consisting of a first audio and a phase inverter amplifier. Any hum in this stage is fed into the push-pull input and is amplied by the push-pull stage. It has been common practice to provide extra filtering to reduce hum in the D. C. supplied to the anode circuits of said preceding stage. While the hum voltage is fed to the anodes of the first audio and phase inverter stages symmetrically, there is another hum voltage superimposed upon the anode of the phase inverter tube only, that is, the hum voltage fed to the grid of the inverter tube along with the signal, and this voltage is changed in phase. Ordinarily these components on the anode of the phase inverter cancel each other, leaving the hum voltage on the anode of the first audio tube unopposed, and unbalanced, to be impressed upon the input circuit of the output stage.

The features of my invention which I believe to be novel are set forth with particularity in the appended claims. My invention, however, both as to its organization and method of opera- 4 claims. v(ci. 179-171) tion, together with further objects and advantages thereof, may best be understood by reference to the following description taken in convnection with the `accompanying drawing, in

Which:

Fig. 1 is aA schematic diagram of a phase inverter and push-pull audio frequency amplifier` circuitr with symbols lcorresponding to those in my formulae used to explain the invention;

Fig. 2 is a schematic diagram of a practical application of thesame circuit, and power supply, giving actual values used in apparatus made in accordance with the invention; and` Fig. 3 is a schematic vdiagram of another typev of phase inverter embodying my invention.

Referring to Fig. l, an audio frequency amplifier, as of a radio receiver, phonograph amplifier or both, is arranged to be energized from a rectified alternating current source of power, shown more completely in Fig. 2. The amplifier comprises a first audio relay, preferably a thermionic amplifier device T1, having an input electrode or grid l, a cathode l3, and an anode 5. The input electrodev l lis connected to a source of signals, notshowmlwhich may be a detector circuit of a radio receiver or a phonograph pickup circuit. The anode circuit impedance of device T1 is represented by R111. Another thermionic amplifying device T2, whose internal anode impedance is represented by Rpz; is shown for inverting the phase of the audio frequency signals degrees in accordance with the teachings of Gorton 1,654,075, dated4 December 27, 1927. While shown as separate devices, T1 and T2 may be combined in one envelope, as shown in Fig. 2, in the apparatus made according to my invention. An input electrode 'l of device T2 is connected to a potentialdivider Rg1 and Rain the A. C. output circuit of device T1. The output electrodes, or anodes, 5y and 9 of amplifying devices T1 and T2 are D. C. connected through coupling impedance ,elements or resistors RLI and Rm, respectively,to a high voltage terminal El of a rectified and filtered'powerv source (Fig. 2). EH represents the hum or variation voltage component in the power source output circuit. The same output electrodes are A. C. coupled in signal transfer relation through capacitors C1 and C2, respectively, to' resistors Rgi and Rg2, respectively,4 and to the input electrodes Il and I3 of amplifying devices T3 and T4, respectively, operating in push-pull relation.

The hum voltage EH from the rectified power supply sourceis of the order of a fraction of a volt in most radio receivers using conventional 3 rectifier and filter circuits, and is fed to the grid of amplifier device T3 through resistor RLi. When a large coupling capacitor Ci is used, the hum voltage appears across the input circuit of amplifier device T3 as voltage EHi, wherein:

RvlRL EH1=EH Rvll'Rll RPI-R11 RIA Rpl'i-Rzl Let and We have EH1=EH R1+RL1. (la). Similarly,

R2 E =E 2 2 ER2+RL2 where Enz is the hum voltage which appears across the grid circuit of tube T4. Em may or may not be equal to Em in magnitude, but E122v is in phase with Em if large coupling capacitors Ci and C2 are used.

However, a portion of the hum voltage Em is fed to the grid of tube T2 which is amplified and appears across the grid of tube Ti as Em. For proper operation of the phase inverter, T2, the stage gain is exactly equalv to Gain (Ph. 1112):@ Re Consequently, EH 3=EH1/180=EH1 (COS Sil] 180=1EH1 The resultant hum voltage appears across the grid circuit of tube Ti as Earl-E113 or Ein-Em. The purpose of this invention is to make EH2+EH3=EH1 both inv magnitude and in phase at the hum frequencies. This is done by properly selecting the values of Rm and RL2 so that Waffle-wrs 3) Under these conditions,

EH2=2-EH1 EH3=EH1 So that When the values of the resistors Rm and RLz are made in accordance with the above derivations, the hum voltage appearing across each input of the amplifiers of the push-pull stage will be equal in magnitude and in phase, hence will be balanced out in the anode output circuits `of the push-pull stage in the divided primary P of the output transformer. An improvement of better than times in hum level, compared withv results of conventional circuits, was obtained in in actual circuit made in accordance with my invention and shown in Fig. 2.

Referring to Fig. 2, amplifiers Ti and T2 are combined in one envelope, a type known as the RCA-6SC7 tu'be, having two triodes with a common cathode 3 as the first audio and phase inverter stage, and having a single ended, or one sided input and a double ended, or divided balanced output, as for push-pull operation. In accordance with my invention, as illustrated in above derivation formulae, the ratio of Rm to Rm is such that the hum voltages impressed upon the input electrodes of the push-pull output stage are equal and of like sign, thereby cancelling out. Whereas in conventional circuits the resistors corresponding to Rm and HL2 are of the same order of magnitude, in accordance with my invention they are quite different in value, in accordance with Equation 3 above, e. g., 390,000 and 180,000 ohms, respectively. The proportion of the values of these resistors is such that the hum voltage impressed through the phase inverter T2 upon the input of the pushpull stage is twice that from the anode circuit of the first audio amplifier Ti. The phase inverter T2 is fed from the output of T1 through potentiometer Rgi and Ru. The ratio of Rgi-l-Ro to Ro is made equal to the amplification factor of the phase inverter T2. The amplified hum voltage at the anode of T2, derived from R21 and Rp, is half that at the anode output arriving through the anode resistor R12 from the power supply and opposite in sign or phase. The difference gives the same hum voltage impressed upon the grid of amplifier T4 from amplifier T2 as is impressed upon amplifier T3 from amplifier Ti. A conventional power supply circuit S comprises a transformer 2|, rectifier 23, filter resistors 25 and 21, and capacitors 28, 29 and 3l.

By way of example, referring to Fig. l, if a given hum voltage exists on the Z50-volt terminal E of the power supply and, after the drop through the resistor Rm, there is 0.1 volt applied to the anodey 5 of amplifier Ti at point B, then there willv be 0.2 volt at point D as a result of the smaller drop through resistor Rm. A selected small proportion of; the hum voltage in the output circuit of the first audio amplifier T1 is picked o the potentiometer at point F between resistors R21 and R0 and applied along with the signal voltage to, the input ofthe phase inverter T2 so that 0.1 volt appears on the anode 9. Atv point D there will then exist the. difference voltage, or TG2-0,120.1 volt. There'will, therefore, be applied to each input circuit of the push-pullamplifiers T3 and T4 a hum voltage Aof +01 volt, which cancels out in the anode circuits of T3 and T4.

The non-symmetrical arrangement of resistors inthe. hum neutralization system, described above,

does not disturb the symmetry of signal voltages.

It will be apparent, therefore, that without dele.

teriously affecting the normal signal functions of the first audio and phase inverter circuits feeding the push-puh stage, I have provided, at practically no additional cost and with no new parts and complications, a novel circuit for canceling hum voltage in the anode supply circuit to the first audio and phase inverter stage, thereby reducing to a minimum the overall hum disturbance.

Referring to Fig. 3, I have shown my invention with another type of phase inverter, the divided or split anode-cathode output type as disclosed in U. S. Patents 2,052,730 to Stoutenburgh and' 2,027,054 to Miessner. A thermionic device T5, preferably a triode with anode 3.5, control electrode 3l' and indirectly heated cathode 39, is connected to an audio signal source at terminal M, which may be the output of the'first audio amplier in a radio receiver.' The anode 3,5 is supplied with voltage from terminal E of a power source, similar to that in Fig. 2, through a resistor 43 of the order of v27,000 ohms. The anode is coupled inthe usual manner to one terminal 45 of a push-pull amplifier stage or other balanced output circuit, as shown in Figs. 1 and 2. The cathode 39 is connected to ground through resistors 41 and 49, and is coupled to the other input terminal 5I of the push-pull amplifier or balanced load. Resistor 49 is large compared to resistor 41. Resistor 49 is of the saine order of magnitude as resistor 43. The control electrode 31 receives its bias voltage through resistor 41 by way ofa resistor 53 connected to a point 60 between cathode resistors 41 and 49. Resistors 41 and 49 function as a tapped single resistor common to input and output circuits and provide degenerative feedback. This type phase inverter has a gain of only unity, but can still be termed an implifier as in the case of Figs. 1 and 2. The anode output may be termed the amplifier side and the cathode output the inverter side of the divided output of the stage.

The anode circuit is subject to hum from terminal E of the power supply source S, as in Fig. l, the hum being impressed upon anode and cathode by way of resistors 43, 41 and 49. A portion of the hum voltage is impressed upon the control electrode 31 by way of the grid leak resistor 53. Practically the same hum voltage, however, appears on the control electrode and cathode and thereby is nullilied, so far as the relaying action of the tube is concerned, and does not introduce hum of opposite phase into the anode circuit to oppose that impressed upon the anode through resistor 43. Furthermore, the cathode to ground circuit impedance, by reason of the degenerative cathode follower action, is low as compared with the anode resistance of the tube. Hence the hum voltage impressed by the cathode 39 upon the input electrode7 terminal 5|, of on side of the following push-pull stage is small compared with that impressed by the anode 35 upon the other side, terminal 45, of the push-pull stage.

According to my invention, the hum voltage in the output from the cathode 39 is increased sufliciently to balance that from anode 35 by means of a branch circuit, comprising resistor 59 and blocking capacitor 51 connected from the point E, in the power supply output which supplies the anode 35, to point 59 in the circuit of cathode 39. The branch circuit may be connected directly to the cathode 39, if desired, although the point 60 is nearly as high as the cathode potential by reason of the large ratio of resistance of resistor 49 to resistor G1. The latter is sometimes bypassed, leaving only the coupling resistance of 49. The sizes of the different components will be determined by various factors such as the type of tube T5, whether the input thereto is of high or low impedance, etc., as will be obvious to those skilled in the art. The size of capacitor 51 will be related to that of Ci in the matter of avoiding undesired phase shift. While resistor 59 has been shown as adjustable for the purpose of obtaining hum balance in the two sides of the output circuit, it will ordinarily be fixed in production.

While a few extra elements apparently have been added in this modification to obtain hum reduction, the expense has been increased little, if any, for the following reason: To obtain comparable results in the usual manner, extra iiltering has been found necessary to reduce hum volt- 6'" age'from terminal E. It seems apparent, therefore, that the results in the case of Fig. 3 are within the objects of the invention, as in the. case of Fig. 2.

I claim as my invention:

l. In an amplifier phase inverter system having a single sided signal input and a divided output circuit, first and second thermionic devices each having a control electrode, an anode and a cathode, a power source having a point of high positive potential for supplying direct current with a fluctuating voltage component to said anodes, said first device having its input electrode connected to said single sided input circuit and its output electrode to one side of said divided output circuit, a shunt potential divider in said one side having a relatively low potential point between a high resistance section Rgi and a low resistance section Ro, said portions having a ratio such that thesum o f Rgi and Ro to Re substantially equals the amplification factor of said second device, said second device having its input electrode connected to said point in said potential divider in said one side of said divided output circuit for picking up amplified signal voltage and a portion of the fluctuating component, which component appears at the anode of said second device in opposite phase and at a voltage substantially equal to that on the anode of said first device, first and second impedance elements connecting the anodes of said first and second devices, respectively, to said power source point, said second element being smaller in impedance than said rst element in a ratio to impress substantially twice the fluctuating component on the anode of said second device to produce resultant iiuctuating components of substantially like magnitude and phase on both sides of said divided output circuit.

2. The invention as set forth in claim 1, wherein said impedance elements are resistors the first of which has substantially twice the value of resistance as the second.

3. In a push-pull amplifying system, an amplifier-inverter stage comprising first and second amplifying devices having a single sided signal input and a two sided divided output circuit arranged to be energized by a rectified alternating current power source for supplying direct current with an undesired hum voltage component, said first amplifying device having a control electrode connected in said input circuit and an output electrode connected to the rst side of said output circuit, a first load resistor connecting said output electrode to a terminal of said power source to receive therefrom said direct current with said component, a potential divider connected in said output circuit in shunt with said first side, said divider having a relatively low potential point between a high resistance section Rgi and a low resistance section Ro having a ratio therebetween such that the sum of Rgi and Ro to Ro substantially equals the amplification factor of said second device, said second amplifying device having an output electrode connected to the second side of said output circuit and a control electrode connected to said point on said divider for receiving a portion of amplified signal energy along with said undesired hum component, said component being amplified by said second device and appearing on its output electrode as substantially the same voltage but in reversed phase relative to the component on said output electrode of said first device, and means comprising a second load resistor of the order of half the resistance of said first load resist'o'ri connecting said'output electrode-of` said' second device to said terminal forsupplying sub#- stantially twice the hum voltage. component to said last named output electrodefthanV is supi plied to said output electrode of saidrrst'devi'ce through said first resistor and of thesame phase, whereby the net hum component impressed'upon said second side ofv said balanced output` isrsubstantially equal and of like phase to that im@ pressed upon said rst side of said balanced output circuit;

4. The invention as set forth-in' claim 3, where@ and phase on'the two sidesof said outputcircuitv cancel out in said transformer.

WEN YUAN PAN.`-

REFERENEs.` CITE.

, The followingv references arev of" rec'ordin the'f l'e" Of this" 'patenti UNITED STATES PATENTS

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